Embodiments according to the invention are hereinafter described with reference to the accompanying drawings.
The intermediate regions 16 and the shoulder regions 18 have transverse grooves 20 arranged in parallel at predetermined intervals in the circumferential direction. The transverse grooves 20 extend in the tread width direction, and cross the circumferential grooves 12. Thus, the intermediate regions 16 and the shoulder regions 18 have block arrays having a number of blocks 22 sectioned by the circumferential grooves 12 and the transverse grooves 20 and arranged in line in the tread circumferential direction. The center region 14 has no transverse groove, and thus provides a rib 24 which is sectioned by the two circumferential grooves 12, 12 and continuously extends in the tread circumferential direction.
Each side of the blocks 22 and the rib 24 has a zigzag shape. More specifically, each of the blocks 22 in the intermediate region 16 has sides 22A, 22A facing the circumferential grooves 12, 12, and each of the sides 22A, 22A has a plurality of edges 26 (two edges 26 in this embodiment) extending from a block surface 22B to a groove bottom 12A and projecting into the corresponding groove 12 to have a step shape. Thus, both the sides 22A, 22A of the blocks 22 are zigzag-shaped. The similar edges 26 are formed only one of the sides 22A of the blocks 22 in the shoulder region 18 facing the corresponding circumferential groove 12 such that the side 22A having the edges 26 can be zigzag-shaped. The similar edges 26 are further formed on both sides 24A, 24A of the rib 24 in the center region 16 facing the circumferential grooves 12, 12 at predetermined intervals in the circumferential direction. These edges 26 on the sides 24A, 24A of the rib 24 extend from a rib surface 24B to the groove bottom 12A such that both the sides 24A, 24A are zigzag-shaped.
The edges 26 project from the block sides 22A and the rib sides 24A in directions substantially perpendicular to the block sides 22A and the rib sides 24A. More specifically, as illustrated in
As illustrated in
As illustrated in
The edges 26 formed on the sides 24A of the rib 24 have the same structure as that of the edges 26 formed on the sides 22A of the blocks 22. The surfaces of the respective blocks 22 and rib 24 have sipes 34 extending in the tread width direction. The sipes 34 are cuttings having small width, and are wavy and zigzag-shaped in this embodiment.
According to the tire in this embodiment discussed above, the edges 26 forming the zigzag shapes of the peripheral sides of the blocks 22 and the rib 24 have steps formed by the bent portions 28 having obtuse angles in the depth direction of the grooves 12. Thus, as illustrated in
Since the edges 26 are formed not only on the sides 22A facing the circumferential grooves 12 but also on sides 22C facing the transverse grooves 20, clogging of the transverse grooves 20 by snow or mud can be further prevented.
According to this embodiment, the edges 26 and the inclination of the step shapes of the edges 26 formed on the left side 22A facing the corresponding circumferential groove 12 are opposite to those on the right side 22A facing the corresponding circumferential groove 12. This structure is applicable to a tire whose rotation direction is not fixed. Similarly, the edges 26 and the inclination of the step shapes of the edges 26 formed on the front side 22C facing the corresponding transverse groove 20 are opposite to those on the rear side 22C facing the corresponding transverse groove 20. This structure provides excellent effect for preventing clogging of the transverse grooves 20 during turning to both the left and right.
Other parts are similar to those in the first embodiment, and similar operations and advantages are offered according to this embodiment.
According to this embodiment, the edges 26 have bent portions 28 (curved portions) curved such that obtuse angles are formed, and thus the edges 26 have wavy step shapes in the depth direction of the grooves 12 as viewed from the block sides 22A as the front surfaces. The obtuse angles of the curved portions 28 herein refer to obtuse angles formed by linear portions when the linear portions are present above and below the curved portions 28, and obtuse angles formed by tangential lines of curvilinear portions above and below the curved portions 28 when the linear portions are not present.
Other parts are similar to those in the first embodiment. Similarly to the above embodiments, snow or mud having entered the grooves 12 easily moves due to the presence of the curved portions 28 having obtuse angles as shown in
According to this embodiment, the edges 26 have cornered portions 28A having obtuse angles and curved portions 28B having obtuse angles, and thus the edges 26 are step-shaped. Each of the curved portions 28B is disposed between an adjoining pair of the lower inclined surface 32 and the upper step 30, and each of the cornered portions 28A is disposed between an adjoining pair of the lower step 30 and the upper inclined surface 32.
Other parts are similar to those in the first embodiment. Similarly to the above embodiments, snow or mud having entered the grooves 12 easily moves due to the presence of the steps 30 having obtuse angles (movement directions of snow are indicated by arrows in the figure). In this case, the snow or mud is gradually discharged to the rear during rotation of the tire.
While the example of the tread pattern having the blocks 22 and the rib 24 has been discussed in the above embodiments, the invention is applicable to other types of tread patterns such as a tread pattern having only a block, and a tread pattern having only a rib. It is therefore possible to conclude that the structure of the edges 26 is applicable to a tread pattern including a block and/or a rib.
A pneumatic radial tire in the first embodiment (Example 1) and a tire in the comparative example having an edge structure shown in
Snow braking ability: the vehicle running on a snow road was ABS braked at the running speed of 40 km/h, and the braking distance was measured.
Snow accelerating ability: the stopping vehicle was accelerated in the L range on a snow road to adjust the engine revolution to 3,500 rpm. Then, the seconds required for the vehicle under 3,500 rpm to advance for the distance of 20 m was counted.
According to the results of Example 1, 10% improvements of both the snow braking ability and the snow accelerating ability from the results of Comparative example 1 were recognized. Thus, the snow performance was enhanced in Example 1.
Accordingly, the pneumatic tire of the invention is appropriately used particularly for a winter tire such as a studless tire and for an off-road tire which requires high mud performance. The invention is also applicable to various other types of pneumatic tires.
Number | Date | Country | Kind |
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2006-115028 | Apr 2006 | JP | national |